磷酸解在瘤胃细菌普氏栖瘤胃菌对纤维二糖和纤维糊精代谢中的作用
Role of phosphorolytic cleavage in cellobiose and cellodextrin metabolism by the ruminal bacterium Prevotella ruminicola.
作者信息
Lou J, Dawson K A, Strobel H J
机构信息
Department of Animal Sciences, University of Kentucky, Lexington 40546-0215, USA.
出版信息
Appl Environ Microbiol. 1996 May;62(5):1770-3. doi: 10.1128/aem.62.5.1770-1773.1996.
Abstract
In bacteria, cellobiose and cellodextrins are usually degraded by either hydrolytic or phosphorolytic cleavage. Prevotella ruminicola B(1)4 is a noncellulolytic ruminal bacterium which has the ability to utilize the products of cellulose degradation. In this organism, cellobiose hydrolytic cleavage activity was threefold greater than phosphorolytic cleavage activity (113 versus 34 nmol/min/mg of protein), as measured by an enzymatic assay. Cellobiose phosphorylase activity (measured as the release of P(i)) was found in cellobiose-, mannose-, xylose-, lactose-, and cellodextrin-grown cells (> 92 nmol of P(i)/min/mg of protein), but the activity was reduced by more than 74% for cells grown on fructose, L-arabinose, sucrose, maltose, or glucose. A small amount of cellodextrin phosphorylase activity (19 nmol/min/mg of protein) was also detected, and both phosphorylase activities were located in the cytoplasm. Degradation involving phosphorolytic cleavage conserves more metabolic energy than simple hydrolysis, and such degradation is consistent with substrate-limiting conditions such as those often found in the rumen.
摘要
在细菌中,纤维二糖和纤维糊精通常通过水解或磷酸解作用进行降解。普氏栖瘤胃菌B(1)4是一种非纤维素分解型瘤胃细菌,具有利用纤维素降解产物的能力。通过酶促测定发现,在这种生物体中,纤维二糖水解活性比磷酸解活性高三倍(分别为113和34 nmol/分钟/毫克蛋白质)。在以纤维二糖、甘露糖、木糖、乳糖和纤维糊精为碳源生长的细胞中发现了纤维二糖磷酸化酶活性(以无机磷酸(Pi)的释放量来衡量,>92 nmol Pi/分钟/毫克蛋白质),但在以果糖、L-阿拉伯糖、蔗糖、麦芽糖或葡萄糖为碳源生长的细胞中,该活性降低了74%以上。还检测到少量的纤维糊精磷酸化酶活性(19 nmol/分钟/毫克蛋白质),两种磷酸化酶活性均位于细胞质中。与简单水解相比,涉及磷酸解作用的降解能保存更多的代谢能量,这种降解与瘤胃中常见的底物限制条件相一致。
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